Method and system for avoiding power outages at the base station in cellular system using variable rate transmission

ABSTRACT

The present invention discloses a method and system for discarding the least amount of data in case a power outage is expected to occur in some timeslot during a future frame. The present invention discloses using Base Station (BS) information on the power transmitted during the last frame, along with information on the total amount of data, and the priority assigned thereto, that the BS has to transmit during upcoming frames, to make decisions on the type and quantity of data that should be removed to avoid severe power outage in the upcoming frames.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No. 10/272,874, filed Oct. 17, 2002, which in turn claims benefit of U.S. Provisional Application No. 60/381,567, filed on May 16, 2002, which is incorporated by reference as if fully set forth herein.

FIELD OF INVENTION

The present invention relates to the field of wireless communications. More specifically, the present invention is related to third generation cellular systems employing variable rate transmission at the downlink.

BACKGROUND

A third generation cellular system uses radio network controllers (RNC) and base stations (BS). Traffic from the core network to the user (downlink) is routed by the RNC to the BS(s) best able to serve a given user. The data sent by the RNC to the BS for a given user is segregated into transport channels (DCHs), each having their own characteristics in terms of coding type, rate and interleaving. The BS periodically collects the data in the form of transport blocks from the RNC, applies the appropriate coding and interleaving for each DCH, multiplexes the data from these different DCHs, and transmits it on the appropriate physical channel (DPCH) or DPCHs. The DPCH(s) is defined in terms of spreading code and, in case of discontinuous transmission (TDD), timeslot.

The power at which signals are transmitted on a given DPCH for a given user depends on several factors such as the path loss between the user and the BS, the interference level perceived by the user, and the signal-to-interference ratio (SIR) required for satisfactory transmission. The required SIR for a given user in a given DPCH may depend on the amount of data to be transmitted from the different DCHs during a specific time period (frame). This amount of data can be referred to as a transport format combination (TFC).

The user periodically requests the BS to adjust its power up or down using an uplink channel as the SIR it experiences varies down or up, respectively. The BS may decide to satisfy the request from the user or not. In a given timeslot, the total power used to transmit all DPCHs cannot exceed a certain threshold. If the BS finds itself in a situation where it is about to violate the threshold, the BS has to reduce the power of every DPCH (by the same relative amount) to avoid exceeding the threshold. This situation is referred to as a power outage.

Congestion is a general term that encompasses any situation where the BS is not able to satisfactorily transmit all the data sent by the RNC to the various users or user equipment (UE) connected to the BS. This may be due to a lack of hardware resources, processing power or transmission power. In order to provide a mechanism for the BS to prioritize between DCHs in case of congestion, the RNC assigns a priority to every DCH: the frame handling priority (FHP). The FHP is assigned by the RNC and transmitted to the BS so that the most important data gets through in case of congestion.

This approach, however, fails to indicate how much low priority data has to be removed to ensure avoidance of severe power outage. A method and system are therefore needed for removing the optimal amount of data in case of congestion, taking into account the power requirements and the FHP of the data.

SUMMARY

The invention is a method and system for avoiding power outages at the base station in cellular systems using variable rate transmission. When congestion is encountered, the invention removes the optimal amount of data while taking into account the power requirements and the frame handling priority of the data.

BRIEF DESCRIPTION OF THE DRAWING(S)

FIG. 1 is a flow chart showing a method for avoiding power outages at the base station in accordance with an embodiment of the present invention.

FIG. 2 is a system wherein the optimal amount of data is removed when congestion is encountered in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

The present invention uses base station (BS) information regarding the power transmitted during the last frame, along with information regarding the total amount of data the BS has to transmit during upcoming frames, to make decisions on the type and quantity of data that should be removed to avoid a severe power outage in the upcoming frames. This allows the BS to determine not only which data should be removed, but also how much. The BS also considers the Frame Handling Priority (FHP) of the data in its decision-making. In situations where data needs to be removed, the invention removes data by order of priority and minimizes the amount of data that is removed in order to avoid an outage.

As mentioned, data sent from the RNC to the BS for a particular user is segregated into transport channels (DCHs). The data from a set of DCHs is multiplexed into a coded composite transport channel (CCTrCH). A CCTrCH is transmitted on a certain number of physical channels (DPCHs) that are allocated to the CCTrCH. The number of DPCHs that are used by a CCTrCH in a given frame depends on the amount of data that has to be transmitted during that frame.

When data from a DCH is discarded, the number of DPCHs required to support the data transmission for this user may be reduced. If some of the DPCHs that are no longer needed are in a selected timeslot, the transmission power requirement (P_(s;n)) for that timeslot will also be reduced. The present invention therefore evaluates the effect tagging different combinations of DCHs for data discard has on the P_(s;n) of a selected timeslot. The P_(s;n) of a selected timeslot may be recomputed and compared to a predetermined threshold (P_(thr)), which is indicative of the maximum allowed transmission power, while making assumptions that alternate between the data of various DCHs being transmitted and discarded. This enables the BS to select for transmission/discard a combination of DCHs of a selected timeslot that results in the optimal amount of data being discarded while ensuring that the P_(s;n) of the selected timeslot does not exceed P_(thr).

Before the BS can process (i.e. code, interleave and multiplex) and send the data for a particular DCH, it must have received data from the RNC and buffered the data that will be transmitted during the next n frames, where n is the number of frames over which this DCH is interleaved. The corresponding duration is commonly referred to as the transmission time interval (TTI) which varies from one DCH to another depending on the nature of the carried data. Thus, the data for a given DCH is buffered and sent every n frames.

In every frame, the BS may estimate the P_(s;n) of every timeslot for the next frame, or if desired the next several frames, based on the data that will be transmitted for the different DCHs and the currently used transmission powers. If the BS determines (by comparing P_(s;n) to P_(thr)) that the risk of outage is significant for a particular timeslot in an upcoming frame, that timeslot is selected for further evaluation. That is, the BS will look at the buffered data scheduled for transmission in the next frame(s), and discard the data of some DCHs so that P_(s;n) in the affected timeslot and frame(s) does not exceed P_(thr). The P_(thr) may be adjusted to make the method more or less aggressive.

In order to compute a P_(s;n) for a future frame, the following information is either assumed or known:

The transmission power of every DPCH of every CCTrCH for the future frame(s).

The transport format combination (TFC) of every CCTrCH during the future frame(s), as the TFC determines the number of DPCHs that are used.

For CCTrCHs having no data during the future frame, whether or not a special burst is expected to be sent.

The transmission powers of every used DPCH, however, are not known accurately even for the next frame. Therefore, the method of the present invention simply uses the latest transmission powers reported by Layer 1 control (i.e. Layer 1 of the BS) for computing P_(s;n) estimates for any future frame. The latest transmission powers reported by Layer 1 control are preferably the ones which were used in the current frame, or the one before if the information is not made available in time.

The P_(s;n) in timeslot s may be computed, for example, according to: $\begin{matrix} {{P_{s;n} = {\sum\limits_{k = 1}^{N_{k}}{{u_{k}\left\lbrack {s,{c_{k}(n)},{d_{k}(n)}} \right\rbrack}{g\left( {k,{s;n}} \right)}}}},} & {{Equation}\quad 1} \end{matrix}$ where g(k, s;n) is the assumed transmission power, at frame n, of one DPCH used by CCTrCH k in slot s; N_(k) is the number of users; c_(k)(n) is the expected TFC of CCTrCH k at frame n; d_(k)(n) indicates if a special burst is expected to be sent at frame n (note: if a special burst is expected it implies that there is no data in the TFC); and u_(k)(s, c, d) is the number of DPCH's used by CCTrCH k in timeslot s if TFC c is sent or if a special burst is sent (where d=1 indicates that a special burst is expected to be sent).

Once P_(s;n)s are calculated for every timeslot in the next n future frames, they are compared to P_(thr). If the method calculates that P_(s;n) exceeds P_(thr) in at least one timeslot and frame, that timeslot is evaluated for data discard. If there is more than one timeslot where P_(s;n) is higher than P_(thr), the timeslot having the highest P_(s;n) is selected first and evaluated for data discard. The remaining timeslots will be evaluated in order of decreasing P_(s;n). If, in contrast, there are no timeslots having a P_(s;n) that exceeds P_(thr), the method does nothing for this frame(s) and sends all data.

The DCHs of a timeslot selected for consideration for data discard are referred to as “concerned” transport channels (DCHs). The concerned DCHs are considered by the present invention to be defined as follows:

There is data to deliver for this DCH(s) in the next frame.

The DCH(s) is part of a CCTrCH which is “involved” in a troubled timeslot, i.e. a timeslot having a P_(s;n) which exceeds P_(thr). A CCTrCH is said to be “involved” in a troubled timeslot if at least one of the DPCHs onto which it is mapped is in that timeslot, as explained above.

The concerned DCHs are sorted according to a predetermined criteria. Preferably, the DCHs are sorted first by frame handling priority (FHP) of the DCH (low FHP's first) and second by the “related” transmission power of the DCH (high powers first). The “related” transmission power of a DCH is defined as the transmission power of the CCTrCH to which the DCH belongs. Thus, within a particular FHP value, the method will affect first the DCHs which constitute CCTrCHs having the highest power requirements. Those CCTrCHs could belong to users that have high path losses due to their unfavorable locations with respect to the serving BS.

The method then puts a “tag” on the first DCH of the list and re-computes P_(s;n) for the selected troubled timeslot and frame as previously described, but now assuming that the tagged DCH will send no data. If P_(s;n) is still above P_(thr), it will proceed with the next DCH on the list, and continue until P_(s;n) falls below P_(thr) or until there are no more DCHs on the list.

At this point, the method continues despite the fact that P_(s;n) may be below P_(thr) because it is possible that some DCHs that have been tagged for discard could be untagged. That is, it is possible at this point that certain DCHs may be restored without causing P_(s;n) to rise above P_(thr) (or possibly to rise at all). Those DCHs should be spared. Therefore the method will go back in the reverse order of the DCH list and re-compute P_(s;n), tentatively removing the tag of every DCH successively and checking if P_(s;n) would increase and go back above the threshold. If removal of a particular DCH's tag does not result in P_(s;n) rising above P_(thr), that DCH's tag is removed. If, in contrast, removal of a DCH's tag causes P_(s;n) to rise above P_(thr), that DCH is retagged and the data therein will not be sent. The process ends after all tagged DCH's have been re-checked.

After the discard procedure has been completed for the first (i.e. the worst) troubled timeslot, the method may start over, as desired. In that case, P_(s;n) is re-computed for all of the other timeslots and the method starts over with the new “worst” troubled timeslot, if any (and not including a timeslot for which the discard procedure has already taken place). The reason why P_(s;n) must be re-computed for the other timeslots is that it is possible that P_(s;n) in the other timeslots has decreased after the discard of the data from some DCH's to relieve congestion in another timeslot. This can happen if a CCTrCH uses DPCHs in different timeslots.

The method ends after all troubled timeslots have been processed. Then data is passed to Layer 1 control, with the “tagged” DCH's transmitting no data. In theory, it could happen that reducing the transport format of some DCH's to no data could result in an invalid TFC in some frame. If, after executing the discard procedure, the method finds that this will happen, the method could reduce the transport format of the DCHs that are sent at the same time until a valid TFC is encountered. If this is not possible (because, for example, the data from other DCHs have been sent earlier) the method could then revert to the transport formats offered to the BS by the RNC.

The steps performed to implement the method of the present invention are shown in FIG. 1 and indicated generally with reference numeral 10. Throughout the method, only data from DCHs that belong to a user that is assigned a DPCH in a selected timeslot will be considered for discard.

The method begins in step 12 by identifying troubled timeslots wherein data will be considered for discard. To identify troubled timeslots, an estimate of the P_(s;n) for every timeslot s in the upcoming n frames is computed. The timeslots having a P_(s;n) above a power threshold P_(thr) are identified as troubled timeslots.

The P_(thr) is an adjustable predetermined value based on the maximum allowed power of the BS. The P_(thr) may be any value, but is preferably a multiple such as, for example, one (1) to five (5) times the maximum allowed power of the BS. The P_(thr) may be used to control how aggressively data is discarded. More specifically, the higher the P_(thr), the more conservative the method will be in discarding data. That is, a higher P_(thr) will result in less timeslots being identified as troubled timeslots thereby reducing the amount of DCHs considered for data discard.

In step 14, the method determines whether any troubled timeslots were, in fact, identified in step 12. If there are no troubled timeslots, the method ends in step 15 and may be restarted as desired. If, alternatively, there are troubled timeslots, the method proceeds to step 16 where the troubled timeslot having the highest P_(s;n) is selected. In step 18, the concerned DCHs are identified. As previously explained, data sent by the RNC to the BS for a given user is segregated into a set of DCHs which are multiplexed into a CCTrCH and mapped onto DPCHs for delivery to the user. DCHs using DPCHs in the currently selected troubled timeslot are identified as the “concerned” DCHs.

In step 20, the concerned DCHs are sorted in order of increasing FHP and decreasing related transmission power. The related transmission power of a particular DCH is the transmission power of the CCTrCH to which the DCH belongs. In step 22, D_(max) is defined as the number of concerned DCHs. In step 24, the method determines whether D_(max) is equal to zero. If D_(max) is equal to zero, it means that there are no concerned DCHs in this timeslot and the method returns to step 16 to select the timeslot having the next highest P_(s;n). If D_(max) is not equal to zero, the method proceeds to step 26 where D is defined as the particular concerned DCH out of the group of concerned DCHs being considered and set to one (1). This ensures that the first concerned DCH on the list is considered first thereby allowing the concerned DCH with the lowest priority and highest transmission power to be evaluated first.

In step 28, the D^(th) (i.e. the 1^(st), 2^(nd), 3^(rd), etc.) concerned DCH is tagged for discard. That is, if D is equal to one (1), the first concerned DCH would be tagged for discard. Then, in step 30, P_(s;n) for the selected timeslot is recomputed assuming that the data in the D^(th) concerned DCH will not be sent. Next, in step 32, the method determines whether P_(s;n) is less than P_(thr). If P_(s;n) is less than P_(thr), the method proceeds to step 36 where the D^(th) concerned DCH is untagged so that the method may confirm whether that DCH necessarily needs to be discarded. If P_(s;n) is not less than P_(thr), the method determines, in step 34, whether D is equal to D_(max), i.e. whether all of the concerned DCHs have been considered. If D is not equal to D_(max), it means that all of the concerned DCHs have not been considered and the method proceeds to step 35. In step 35, D is increased by one so that the next concerned DCH on the list may be tagged for discard and considered, as explained above.

Once steps 28 through 35 have been completed, as needed, for each of the concerned DCHs, the data required to reduce P_(s;n) below P_(thr) has been tagged for discard. There is a risk, however, that too much data may have been tagged for discard. The method, therefore, continues by evaluating the effect of tagging for discard different combinations of concerned DCHs. This is done to ensure that the optimal amount of data is being discarded so that too much data is not unnecessarily discarded while reducing the P_(s;n) of a selected timeslot.

As mentioned above, the D^(th) concerned DCH is untagged in step 36. Then, in step 38, a temporary estimate of transmission power requirement (P′_(s;n)) is computed. The P′_(s;n) is computed taking into account the current status (i.e. tagged or untagged) of the concerned DCHs.

In step 40, the method evaluates P′_(s;n) in relation to P_(s;n) and P_(thr). Specifically, in step 40, the method determines whether P′_(s;n) is greater than P_(s;n) and P_(thr). If P′_(s;n) is greater than both P_(s;n) and P_(thr), it means that P_(s;n) for the selected timeslot cannot be sufficiently reduced with the data in the D^(th) concerned DCH being transmitted. Therefore, if untagging a concerned DCH results in a P′_(s;n) that is greater than P_(s;n) and P_(thr), that concerned DCH is retagged in step 42 resulting in the data in that concerned DCH being discarded. If, in contrast, the method determines in step 40 that P′_(s;n) is not greater than P_(s;n) and P_(thr), it means that P_(s;n) for the selected timeslot may be sufficiently reduced while transmitting the data contained in the D^(th) concerned DCH. In that case, the D^(th) concerned DCH remains untagged and the method proceeds to step 41 where P_(s;n) is set equal to P′_(s;n).

Regardless of whether the D^(th) concerned DCH is retagged or not, the method proceeds to step 44. In step 44, the method determines whether the D^(th) concerned DCH is the first concerned DCH thereby ensuring that all of the concerned DCHs which were previously considered for receiving a tag are similarly reconsidered, in reverse order, for being untagged. This allows the proper combination of concerned DCHs to be tagged for data discard thereby optimizing P_(s;n) in relation to P_(thr) (i.e. selecting the proper combination of concerned DCHs for data discard so that the minimum amount of data is discarded while ensuring that P_(s;n) does not exceed P_(thr)). It is important to note that by optimizing P_(s;n) in relation to P_(thr), the method also causes P_(s;n) to be as close as possible to P_(thr) without, of course, exceeding P_(thr).

If the D^(th) concerned DCH is the first (i.e. D is equal to 1), the method will proceed to step 46. If not, however, the method continues with step 45 where D is increased by one so that the next concerned DCH may be considered for being untagged.

Once all of the appropriate concerned DCHs have been considered (steps 28 to 35) and reconsidered (steps 36 to 45) for data discard, the method will determine in step 46 whether there are any additional timeslots that were previously identified as troubled timeslots in step 12. If there are additional timeslots, the method proceeds to step 48 where P_(s;n) is recomputed. Once P_(s;n) has been recomputed for all of the remaining timeslots, the timeslot that now has the highest P_(s;n) is selected in step 16 and the method continues from there, as described above. If, alternatively, there are no additional troubled timeslots, the method ends (step 50) and the tagged data is not sent.

So as to provide an example of how the method of the present invention may be implemented, assume there are three concerned DCHs, D1, D2 and D3 where D3 has the highest FHP and D1 and D2 have the same FHP. Further assume that P_(thr) is 1.0 W and that DCHs D1, D2 and D3 have individual related transmission powers of 0.1 W, 0.1 W and 1.1 W, respectively.

Given the FHP and related transmission power of the DCHs, they would be sorted as D1, D2 and D3 in step 20 (i.e. increasing FHP first and then decreasing related transmission power). Therefore, for D1, D2 and D3, D is equal to 1, 2 and 3, respectively. Furthermore, assume that the P_(s;n)s when some or all of the data from those channels are as follows:

-   -   D1+D2+D3: 1.3 W     -   D2+D3 only: 1.2 W     -   D3 only: 1.1 W     -   D2 only: 0.1 W     -   D1+D2 only: 0.2 W         As can be seen above, transmitting all three DCHs results in a         P_(s;n) of 1.3 W which is 0.3 above P_(thr). Therefore, data         will need to discarded in order to avoid exceeding P_(thr).

In this example, low priority channels D1 and D2 would be initially tagged for discard. D1 and D2 are the first DCHs tagged for discard because, as mentioned, the concerned DCHs are sorted first according to increasing FHP and then according to their related transmission power. Tagging D1 and D2 for discard, however, is not sufficient to reduce P_(s;f) to P_(thr). That is, discarding the data in DCHs D1 and D2 causes P_(s;n) to drop from 1.3 W to 1.1 W which is still above the assumed P_(thr) of 1.0 W. Therefore, D3 will also be tagged for discard thereby causing P_(s;n) to be below P_(thr). Unfortunately, however, tagging D3 for discard causes P_(s;n) to drop to 0.0 W causing no data at all to be sent. This is overkill, however, because P_(s;n) could have been brought into conformance with P_(thr) by simply discarding the data in D3 and allowing the data in DCHs D1 and D2, although it is of a lower FHP than D3, to nevertheless be transmitted.

This type of situation is taken care of in the untagging phase of the method (steps 36-45). The method would first untag D3. D3's tag, however, would be reapplied in step 42 because, in step 40, the P′_(s;n) would be greater than P_(s;n) and P_(thr) (i.e. P′_(s;n) would equal 1.1 W, P_(s;n) would equal 0.0 W and P_(thr) would equal 1.0 W). It is important to note that the P_(s;n) used in step 42 is the P_(s;n) as affected by the preliminary tags that are placed in steps 26 to 35. That is, in this example, D1, D2 and D3 were all tagged resulting in a P_(s;n) of 0.0 W being calculated in step 30. Therefore, it is that P_(s;n) that is compared to P′_(s;n) in step 40. If, however, P_(s;n) is set equal to P′_(s;n) in step 41, that P_(s;n) will be used in step 40 if the method at step 44 proceeds to step 45 and so on. Generally speaking, whenever P_(s;n) is compared to another parameter, the latest computed P_(s;n) is used.

Returning to the example, once D3's tag is reapplied in step 42, the method proceeds to step 44 where the method determines whether D is equal to 1 (i.e. whether the concerned DCH currently being considered is the first concerned DCH). Since D3 is the third concerned DCH and not the first, the method continues because all of the previously considered DCHs have yet to be reconsidered. Therefore, D will be decreased by 1 in step 45 thereby causing D2 to be untagged in step 36. In step 37, now that D3 and D1 are tagged, but D2 has been untagged, P′_(s;n) will become 0.1 W (1.3 W−1.1 W−0.1 W=0.1 W) in step 38. Therefore, P′_(s;n) will not be greater than both P_(s;n) and P_(thr). That is, P′_(s;n) will be greater than P_(s;n,) but not P_(thr) [i.e. 0.1 W (P′_(s;n)) compared with 0.0 W (P_(s;n)) and 1.0 W (P_(thr))]. Since P′_(s;n) is still below P_(thr) despite the fact that the data in DCH D2 has been untagged, D2's tag is permanently removed. The same thing happens for D1. Therefore, for the situation outlined above, the data in D3 would be discarded while the data in D1 and D2 is transmitted.

Referring now to FIG. 2, a system 100 is shown for avoiding power outages at the BS in cellular systems using variable rate transmission. The system 50 includes a RNC 112, a BS 114 and a UE 116.

Data sent by the RNC 112 to the BS 114 for a given user is segregated into DCHs. The BS 114 multiplexes the data from the DCHs and maps it onto the appropriate DPCHs. The BS 114 may estimate the P_(s;n) of every timeslot for the next frame, or if desired the next several frames, based on the data that will be transmitted for the different DCHs and the currently used transmission powers. Timeslots identified as troubled timeslots (i.e. those having a P_(s;n) which exceeds P_(thr)) are evaluated for data discard.

The data in the DCHs of the troubled timeslots may be evaluated in order to identify the optimal combination of DCHs for which data may be transmitted/discarded. Once the DCHs that result in the optimal amount of data being discarded are identified, data in those DCHs is not sent by the BS 114. The BS 114 may send a signal to the RNC 112 indicating which data was not sent.

Although the present invention has been described in detail, it is to be understood that the invention is not limited thereto, and that various changes can be made therein without departing from the spirit and scope of the invention, which is defined by the attached claims. 

1. A method for avoiding power outages at a base station in wireless systems using variable rate transmission, the method comprising: a) computing a transmission power requirement estimate for every timeslot in at least one future frame; b) identifying timeslots having a transmission power requirement estimate above a predetermined threshold; and c) optimizing the transmission power requirement estimate in relation to the predetermined threshold for each of the identified timeslots.
 2. The method of claim 1 wherein the step of optimizing the transmission power requirement estimate in relation to the predetermined threshold for each of the identified timeslots further comprises: a) identifying the frame handling priority and related transmission power of transport channels having data that will be transmitted on a physical channel in the identified timeslots; and b) discarding data in the transport channels based first on the frame handling priority and second on the related transmission power of the transport channels.
 3. The method of claim 1 wherein the step of optimizing the transmission power requirement estimate in relation to the predetermined threshold for each of the identified timeslots comprises: a) identifying the frame handling priority and related transmission power of transport channels having data that will be transmitted on a physical channel in the identified timeslots; b) applying a tag to various combinations of the transport channels that tentatively indicates that data within the transport channel to which the tag is applied will be discarded; and c) selecting for discard, data within transport channels making up a combination of transport channels that optimizes the transmission power requirement estimate in relation to the predetermined threshold for each of the identified timeslots.
 4. The method of claim 1 wherein the estimate of the transmission power requirement estimate for each timeslot is computed using information from a current frame.
 5. The method of claim 1 wherein the transmission power requirement estimate for each timeslot is calculated based on transmission powers used during the current frame.
 6. The method of claim 1 wherein the predetermined threshold is based on maximum allowed power of the base station.
 7. The method of claim 6 wherein the predetermined threshold is a multiple of the maximum allowed power of the base station.
 8. A system for avoiding power outages in wireless systems using variable rate transmission, the system comprising: a) a radio network controller wherein data is sent to a base station for at least one user; b) wherein data sent from the radio network controller to the base station is assigned a frame handling priority and segregated into transport channels that are mapped onto physical channels for delivery to the at least one user; and c) the base station being adapted to identify timeslots in at least one future frame that have a transmission power requirement estimate above a predetermined threshold and to optimize the transmission power requirement estimate in relation to the predetermined threshold for each of the identified timeslots.
 9. The system of claim 8 wherein the base station identifies timeslots in at least one future frame that have a transmission power requirement estimate above a predetermined threshold by computing a transmission power requirement estimate for every timeslot in at least one future frame and determining whether any of the estimates exceed a predetermined threshold for any of the timeslots.
 10. The system of claim 9 wherein the base station computes the transmission power requirement estimate for each timeslot using information available at the base station in a current frame.
 11. The system of claim 10 wherein the base station computes the transmission power requirement estimate based on transmission powers used during the current frame.
 12. The system of claim 9 wherein the predetermined threshold is based on maximum allowed power of the base station.
 13. The system of claim 12 wherein the predetermined threshold is a multiple of the maximum allowed power of the base station.
 14. The system of claim 8 wherein the base station optimizes the transmission power requirement estimate by discarding data in the transport channels based on first the frame handling priority and second related transmission power of the transport channels.
 15. The system of claim 14 wherein the base station determines which data will be discarded by: a) applying a tag to various combinations of the transport channels that tentatively indicates that data within the transport channel to which the tag is applied will be discarded; and b) selecting for discard, data within transport channels making up a combination of transport channels that optimizes the transmission power requirement estimate in relation to the predetermined threshold for each of the identified timeslots.
 16. A method for avoiding power outages at a base station in a wireless communication system that is configured to transmit communication data in a time frame format that defines time slots in which data on multiple transport channels can be transmitted, the method comprising: calculating a transmission power estimate for every transmission time slot in at least one future frame; identifying time slots having a transmission power estimate above a predetermined threshold in which data on multiple transport channels is to be transmitted; and, discarding one or more transport channels for transmission in such identified time slots such that the transmission power estimate for the identified time slots after discarding transport channels is reduced below the predetermined threshold.
 17. The method of claim 16 wherein the step of discarding transport channels is based on a priority of each transport channel.
 18. The method of claim 17 wherein the step of discarding transport channels is based on a transmission power requirement of each transport channel.
 19. The method of claim 16 wherein the step of identifying time slots is based on a predetermined threshold of a maximum allowed power of the base station.
 20. The method of claim 16 further comprising the steps of: recalculating a transmission power estimate for identified time slots assuming that at least one previously discarded transport channel is reinstated; and reinstating the transport channel assumed to be reinstated where the recalculated transmission power estimate for the concerned time slot remains below the predetermined threshold.
 21. The method of claim 20 wherein the step of reinstating transport channels is based on a transmission power requirement of each transport channel.
 22. The method of claim 20 wherein the step of reinstating transport channels is based on a priority of each transport channel.
 23. The method of claim 16 wherein the step of calculating the transmission power estimate is performed by using transmission power information from a current frame.
 24. A base station adapted to avoid power outages in a wireless communication system that is configured to transmit communication data in a time frame format that defines time slots in which data on multiple transport channels can be transmitted, the base station comprising: means for calculating a transmission power estimate for every transmission time slot in at least one future frame; means for identifying time slots having a transmission power estimate above a predetermined threshold in which data on multiple transport channels is to be transmitted; and, means for discarding one or more transport channels for transmission in such identified time slots such that the transmission power estimate for the identified time slots after discarding transport channels is reduced below the predetermined threshold.
 25. The base station of claim 24 wherein the means for discarding transport channels is configured to discard transport channels based on a priority of each transport channel.
 26. The base station of claim 25 wherein the means for discarding transport channels is configured to discard transport channels based on a transmission power requirement of each transport channel.
 27. The base station of claim 24 wherein means for identifying time slots is configured to use a predetermined threshold based on maximum allowed power of the base station.
 28. The base station of claim 24 further comprising: means for recalculating a transmission power estimate for identified time slots assuming that at least one previously discarded transport channel is reinstated; and means for reinstating the transport channel assumed to be reinstated where the recalculated transmission power estimate for the concerned time slot remains below the predetermined threshold.
 29. The base station of claim 28 wherein the means for reinstating is configured to reinstate transport channels based on a transmission power requirement of each transport channel.
 30. The base station of claim 29 wherein the means for reinstating is configured to reinstate transport channels based on a priority of each transport channel.
 31. The base station of claim 24 wherein the means for calculating a transmission power estimate is configured to calculate the transmission power estimate using a transmission power information from a current frame. 